CZ31516U1 - A device for obtaining nutrients, especially phosphorus, from waste water - Google Patents

Description

Technical field

The technical solution falls within the field of waste water treatment and relates to a device for extracting nutrients, in particular phosphorus, from waste water by separation in the tertiary stage of a waste water treatment plant by selective ion exchange, which makes it possible to extract phosphorus from the waste water in a reusable form; thereby reducing its concentration at the effluent from the sewage treatment plant.

BACKGROUND OF THE INVENTION

Wastewater treatment is undergoing a gradual development, driven by new knowledge in both technological and analytical methods. At present, the trend is not only to remove organic pollution but also to a greater extent to remove nitrogen and phosphorus, and it has already been proven that phosphorus causes eutrophication of surface waters and has a negative impact on the biocoenosis of reservoirs. Therefore, strict emission standards apply to waste water treatment plants (WWTPs) from 10,000 population equivalent. Current technologies commonly used in wastewater treatment plants for phosphorus removal can be divided into chemical and biological. In both cases, phosphorus becomes part of the sewage sludge and is disposed of as waste. Chemical processes for removing phosphorus from wastewater are based on the precipitation of phosphate ions with trivalent metal salts, in particular iron and aluminum (e.g. ferric sulfate, aluminum sulfate, aluminum chloride), as described, for example, in WO 2016/051329 or in WO 2009 / 002801. The respective chemical is added as a solution to various parts of the process, for example under mechanical pre-treatment by direct precipitation, into the activation tank during simultaneous precipitation, or up to the settling tank during tertiary precipitation, in which case the chemical sludge can be separated separately. Biological removal of phosphorus takes place in two ways. The first is the binding of organic phosphorus to cell structures, which is essential for the growth of sewage sludge microorganisms. The highest formation of activated sludge occurs at low age and high load of sludge. An aerobic selector for the purification of waste water including biological removal of phosphorus is disclosed in WO 02/100783. The second is the formation of polyphosphate granules by bacteria, collectively referred to as phosphorus accumulating. These bacteria require a transition from a strictly anaerobic environment to an aerobic or anoxic environment for their life cycle. The anaerobic reactor is generally placed upstream of the activation tank itself, as described, for example, in US 2017/0121197 A1. WO 94/11313 describes a method for biological removal of phosphorus by mixing sewage with activated sludge under anaerobic conditions followed by aeration in a tank. Phosphorus, which is incorporated into the cell structures of bacteria, subsequently becomes part of the sewage sludge. In recent years, the development of technologies that make it possible to extract phosphorus from wastewater in a reusable form, most often as a struvite-based fertilizer, has intensified. These are mainly technologies based on precipitation of struvite from wastewater or sludge water. A method and apparatus in the form of a fluidized bed reactor for recovering struvite or other phosphorus compound, for example in the form of pellets, is described in WO 2005077834. Other methods are based on the thermal treatment of sludge and ash thereof, respectively. The process for high temperature decomposition of ash with chlorine salts is carried out at a temperature of up to 1100 ° C, as disclosed, for example, in US 2009/0183543 A1. The disadvantage of thermal methods is the energy consumption of the process and the high demands on the chemical treatment of ash. The disadvantage of phosphorus precipitation methods is the need to treat large volumes of wastewater and hence the need for large reactors.

SUMMARY OF THE INVENTION The object of the present invention is to provide a new device for extracting nutrients, in particular phosphorus, from waste water, which achieves the transfer of phosphorus from treated waste water to regenerate for further processing, thereby achieving a minimum phosphorus concentration in purified waste water discharged into reduction of phosphorus content in sewage sludge.

The essence of the technical solution

The set goal is achieved by a technical solution, which is a device for obtaining nutrients, especially phosphorus, from waste water discharged from a waste water treatment plant equipped with

The first step consists of an interconnected ion exchange pressure filter and a regeneration solution dosing block, where the inlet of the treated water from the sewage treatment plant is connected to the pressure filter from above. the upper part of the drainage pipe is discharged and in the lower part the drainage pipe of separated water, the drainage pipe of the regenerate and the inlet pipe of the washing water is led out, with the outlet from the regeneration solution dosing block .

It is preferred that the separated water drain line, the regenerate drain line, and the wash water supply line are led out of the pressure filter housing through a common orifice or separately.

It is further preferred that the device is equipped with a prefiltering block which is mounted on the purified water inlet pipe and a conditioning block which is connected to the separated water outlet pipe and the outflow therefrom into the purified water inlet pipe.

The present invention achieves the effect of first allowing the phosphate ions to be concentrated on an adsorption bed composed of a polymeric anion exchange resin enriched with hydrated iron oxide. The product obtained in this step is a regenerate representing a fraction of the original volume of waste water, which contains a high phosphate concentration and is suitable for the subsequent precipitation of phosphorus salts, in particular based on struvite or apatite. It is thus possible to obtain a reusable product, for example a fertilizer, as well as to reduce the phosphorus concentration in the effluent from the sewage treatment plant to below 0.5 mg / l. The benefits of minimizing the biological removal of phosphorus and eliminating the chemical precipitation of phosphorus are both achieving maximum phosphorus concentration in the treated waste water, the phosphorus being selectively recovered in the form of highly concentrated regenerate in the tertiary stage, and reducing phosphorus in sewage sludge where it becomes unusable. The benefit of the tertiary stage for obtaining phosphorus based on selective ion exchange is the possibility of extracting phosphorus from the wastewater in a further usable form and reducing the phosphorus concentration in the wastewater discharged into the watercourse permanently below 0.5 mg / l.

Clarification of drawings

Specific embodiments of the device according to the invention are schematically shown in the attached drawings, where:

Fig. 1 is a technological diagram of the basic version of the device connected to the treated water inlet of the WWTP; Fig. 2 is a technological diagram of the device of Fig. 1 showing alternative connection of regeneration solution dosing unit, regenerate outlet and scrubbing water inlet; Fig. 4 is a flow chart of the device of Fig. 3 showing an alternative connection of the regeneration solution dosing block, the regenerate outlet and the wash water inlet.

The figures showing the schematics of the device according to the invention and the following examples of specific embodiments of the device in no way limit the scope of protection given in the definition, but merely illustrate the nature of the invention.

Examples of technical solutions

The device according to the invention is in the basic embodiment shown in Fig. 1 formed by an ion exchange pressure filter 1, into which the inlet pipe 2 of purified water from the wastewater treatment plant 3 is connected from above. It is equipped with at least mechanical stage 31, biological stage 32 and sedimentation tank 33 The adsorption ion exchange pressure filter i, where the adsorbent is a macroporous weakly basic anion exchanger, generally based on styrene, impregnated with hydrated iron oxide, is generally a vertical pressure vessel consisting of a cylindrical shell ϋ enclosed by unlabeled flanges or arched bottoms where the housings 11 are located between the bottom and the distributor (not shown). Inlet pipe 2 cleaned

The outlet of the regeneration solution dosing block 4 and the pressure filter outlet 1 of the wash water outlet pipe 5 are connected to the water outlet. At the bottom of the jacket Π. A common orifice for the separated water outlet pipe 6, the regenerate outlet pipe 7 and the wash water supply pipe 8 is led out of the pressure filter 1, below the filter intermediate wall 12.

The equipment is then equipped with standard and non-described standard constructional and technological elements such as discharge, venting, sampling, a number of fittings and control, actuating or safety elements or components.

As shown in Fig. 2, the outlet of the regeneration solution dosing block 4 can be fed not into the inlet line 2 of the purified water from the sewage treatment plant 3, but directly from above into the pressure filter i. 8, the washing water is connected to the common orifice of the separated water outlet pipe 6, but can be connected in the bottom part of the jacket 1T separately, as also shown in FIG. 2.

In order to increase the efficiency of the device, its basic design can be supplemented with a prefiltering block 10 and a conditioning block 9, as shown in Fig. 3. The pre-filtration block 10 to remove suspended solids is mounted on the inlet pipe 2 of purified water and the conditioning block 9 for eventual renewal of the ion exchange filter bed of the pressure filter X and lowering the pH, it is connected to the separated water outlet pipe 6 and the outlet from it is discharged into the inlet pipe 2 of the purified water. As with the device shown in FIG. 2, the regenerate drain line 7 and the wash water supply line 8 need not be connected to the common neck of the separated water drain line 6, but may be connected to the bottom of the jacket 11 separately, as shown in FIG. .

The equipment operates in cycles, each cycle always comprising an adsorption phase and a regeneration phase. The washing phase of the adsorption charge is included as needed. In the adsorption phase, the purified waste water is fed through the supply line 2 to the ion exchange pressure filter 1 via a distributor. Phosphate ions are captured in an ion exchange cartridge (not shown) and waste water flows out of the outlet line 6. After the adsorption charge has reached its sorption capacity, the pressure filter is shut down and the second phase is started, ie the regeneration process. During the regeneration, phosphate ions are released and regenerate with a high phosphorus concentration is formed. After the regeneration is completed, the washing phase can be followed by the washing water being fed through the inlet pipe 8 below the filter wall of the pressure filter 1. The washing water flows through the washing water outlet pipe 5 during the washing. After the washing phase is completed, the adsorption phase is again followed.

From the technological point of view, the tertiary stage of waste water treatment is based on the principle of ion exchange on a hybrid ion exchanger, which is enriched with hydrated iron oxide. The iron oxide present allows selectively binding phosphate ions which are subsequently released by the regeneration process. Binary solutions based on sodium hydroxide (NaOH) and sodium chloride (NaCl) serve as regenerating agents. The recovered regenerate is characterized by up to two orders of magnitude higher phosphate phosphorus concentration compared to the original treated waste water. Furthermore, the process significantly reduces the volume, which is up to 99%. Concentration and very significant volume reduction make it possible to treat the regenerate in relatively small technological facilities compared to the need for treatment of the original treated waste water. After pre-treatment of the waste water in the treatment plant 3, which ensures the removal of undissolved substances below 5 mg / l and may be supplemented for this purpose by a pre-filtration block 10, eg sand filtration, microfiltration etc. from which the waste water flows to the adsorption stage of ion exchange pressure filter i, which works cyclically. In the sorption part of the cycle, phosphate ions are adsorbed when the waste water passes through a bed formed by a suitable ion exchanger. is used as process water at the treatment plant 3. After saturation of the sorbent material, the sorbent portion of the cycle is complete and the regeneration portion begins, in which the ion exchange bed is washed with a regeneration solution into which phosphate ions are released. If necessary, the sorbent will be washed with clean water or conditioned according to the manufacturer's instructions for the sorbent material used. The recovered regenerate should be weighed to a larger WWTP where it is

CZ 31516 Ul installed technology for its processing. Another suitable application is simple pH adjustment and subsequent use as a liquid fertilizer.

Industrial applicability

The selective ion exchange phosphorous recovery equipment designed according to the technical solution is useful in the reconstruction of small and medium-sized waste water treatment plants as well as in the construction of new large wastewater treatment plants. The method of treatment of the biological stage of wastewater treatment and subsequent phosphorus recovery can also be used in the reconstruction of existing municipal wastewater treatment plants, where there is insufficient space for building anaerobic reactors upstream of activation.

Claims (4)

PROTECTION REQUIREMENTS Apparatus for extracting nutrients, in particular phosphorus, from waste water discharged from a wastewater treatment plant (3), equipped with a mechanical stage (31), a biological stage (32) and a settling tank (33), characterized in that it consists of interconnected ion exchange by means of a pressure filter (1) and a regeneration solution dosing block (4), wherein the inlet pipe (2) of the purified water from the wastewater treatment plant (3) is connected to the pressure filter (1) from above. ) of the scrubbing water and at the bottom there is a drain pipe (6) of separated water, a drain pipe (7) of regenerate and inlet pipe (8) of the scrubbing water, and into the inlet pipe (2) of purified water ) of the pressure filter (1), the outlet of the regeneration solution dosing block (4) opens. Device according to claim 1, characterized in that the separated water drain line (6), the regenerate drain line (7) and the wash water supply line (8) are led out of the pressure filter housing (11) via a common orifice or separately. Device according to claims 1 and 2, characterized in that it is equipped with a prefiltering block (10) which is mounted on the inlet pipe (2) of the purified water. Device according to one of Claims 1 to 3, characterized in that it is equipped with a conditioning block (9) which is connected to the separated water outlet pipe (6) and the outlet from it is discharged into the purified water inlet pipe (2).